// Copyright 2012 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.

#ifndef V8_HEAP_HEAP_INL_H_
#define V8_HEAP_HEAP_INL_H_

#include <cmath>

#include "src/base/platform/platform.h"
#include "src/counters-inl.h"
#include "src/feedback-vector.h"
#include "src/heap/heap.h"
#include "src/heap/incremental-marking-inl.h"
#include "src/heap/mark-compact.h"
#include "src/heap/object-stats.h"
#include "src/heap/remembered-set.h"
#include "src/heap/spaces-inl.h"
#include "src/heap/store-buffer.h"
#include "src/isolate.h"
#include "src/list-inl.h"
#include "src/log.h"
#include "src/msan.h"
#include "src/objects-inl.h"
#include "src/objects/scope-info.h"
#include "src/objects/script-inl.h"
#include "src/profiler/heap-profiler.h"
#include "src/string-hasher.h"

namespace v8 {
namespace internal {

AllocationSpace AllocationResult::RetrySpace() {
  DCHECK(IsRetry());
  return static_cast<AllocationSpace>(Smi::ToInt(object_));
}

HeapObject* AllocationResult::ToObjectChecked() {
  CHECK(!IsRetry());
  return HeapObject::cast(object_);
}

#define ROOT_ACCESSOR(type, name, camel_name) \
  type* Heap::name() { return type::cast(roots_[k##camel_name##RootIndex]); }
ROOT_LIST(ROOT_ACCESSOR)
#undef ROOT_ACCESSOR

#define STRUCT_MAP_ACCESSOR(NAME, Name, name) \
  Map* Heap::name##_map() { return Map::cast(roots_[k##Name##MapRootIndex]); }
STRUCT_LIST(STRUCT_MAP_ACCESSOR)
#undef STRUCT_MAP_ACCESSOR

#define STRING_ACCESSOR(name, str) \
  String* Heap::name() { return String::cast(roots_[k##name##RootIndex]); }
INTERNALIZED_STRING_LIST(STRING_ACCESSOR)
#undef STRING_ACCESSOR

#define SYMBOL_ACCESSOR(name) \
  Symbol* Heap::name() { return Symbol::cast(roots_[k##name##RootIndex]); }
PRIVATE_SYMBOL_LIST(SYMBOL_ACCESSOR)
#undef SYMBOL_ACCESSOR

#define SYMBOL_ACCESSOR(name, description) \
  Symbol* Heap::name() { return Symbol::cast(roots_[k##name##RootIndex]); }
PUBLIC_SYMBOL_LIST(SYMBOL_ACCESSOR)
WELL_KNOWN_SYMBOL_LIST(SYMBOL_ACCESSOR)
#undef SYMBOL_ACCESSOR

#define ROOT_ACCESSOR(type, name, camel_name)                                 \
  void Heap::set_##name(type* value) {                                        \
    /* The deserializer makes use of the fact that these common roots are */  \
    /* never in new space and never on a page that is being compacted.    */  \
    DCHECK(!deserialization_complete() ||                                     \
           RootCanBeWrittenAfterInitialization(k##camel_name##RootIndex));    \
    DCHECK(k##camel_name##RootIndex >= kOldSpaceRoots || !InNewSpace(value)); \
    roots_[k##camel_name##RootIndex] = value;                                 \
  }
ROOT_LIST(ROOT_ACCESSOR)
#undef ROOT_ACCESSOR

PagedSpace* Heap::paged_space(int idx) {
  DCHECK_NE(idx, LO_SPACE);
  DCHECK_NE(idx, NEW_SPACE);
  return static_cast<PagedSpace*>(space_[idx]);
}

Space* Heap::space(int idx) { return space_[idx]; }

Address* Heap::NewSpaceAllocationTopAddress() {
  return new_space_->allocation_top_address();
}

Address* Heap::NewSpaceAllocationLimitAddress() {
  return new_space_->allocation_limit_address();
}

Address* Heap::OldSpaceAllocationTopAddress() {
  return old_space_->allocation_top_address();
}

Address* Heap::OldSpaceAllocationLimitAddress() {
  return old_space_->allocation_limit_address();
}

void Heap::UpdateNewSpaceAllocationCounter() {
  new_space_allocation_counter_ = NewSpaceAllocationCounter();
}

size_t Heap::NewSpaceAllocationCounter() {
  return new_space_allocation_counter_ + new_space()->AllocatedSinceLastGC();
}

template <>
bool inline Heap::IsOneByte(Vector<const char> str, int chars) {
  // TODO(dcarney): incorporate Latin-1 check when Latin-1 is supported?
  return chars == str.length();
}


template <>
bool inline Heap::IsOneByte(String* str, int chars) {
  return str->IsOneByteRepresentation();
}


AllocationResult Heap::AllocateInternalizedStringFromUtf8(
    Vector<const char> str, int chars, uint32_t hash_field) {
  if (IsOneByte(str, chars)) {
    return AllocateOneByteInternalizedString(Vector<const uint8_t>::cast(str),
                                             hash_field);
  }
  return AllocateInternalizedStringImpl<false>(str, chars, hash_field);
}


template <typename T>
AllocationResult Heap::AllocateInternalizedStringImpl(T t, int chars,
                                                      uint32_t hash_field) {
  if (IsOneByte(t, chars)) {
    return AllocateInternalizedStringImpl<true>(t, chars, hash_field);
  }
  return AllocateInternalizedStringImpl<false>(t, chars, hash_field);
}


AllocationResult Heap::AllocateOneByteInternalizedString(
    Vector<const uint8_t> str, uint32_t hash_field) {
  CHECK_GE(String::kMaxLength, str.length());
  // The canonical empty_string is the only zero-length string we allow.
  DCHECK_IMPLIES(str.length() == 0, roots_[kempty_stringRootIndex] == nullptr);
  // Compute map and object size.
  Map* map = one_byte_internalized_string_map();
  int size = SeqOneByteString::SizeFor(str.length());

  // Allocate string.
  HeapObject* result = nullptr;
  {
    AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
    if (!allocation.To(&result)) return allocation;
  }

  // String maps are all immortal immovable objects.
  result->set_map_after_allocation(map, SKIP_WRITE_BARRIER);
  // Set length and hash fields of the allocated string.
  String* answer = String::cast(result);
  answer->set_length(str.length());
  answer->set_hash_field(hash_field);

  DCHECK_EQ(size, answer->Size());

  // Fill in the characters.
  MemCopy(answer->address() + SeqOneByteString::kHeaderSize, str.start(),
          str.length());

  return answer;
}


AllocationResult Heap::AllocateTwoByteInternalizedString(Vector<const uc16> str,
                                                         uint32_t hash_field) {
  CHECK_GE(String::kMaxLength, str.length());
  DCHECK_NE(0, str.length());  // Use Heap::empty_string() instead.
  // Compute map and object size.
  Map* map = internalized_string_map();
  int size = SeqTwoByteString::SizeFor(str.length());

  // Allocate string.
  HeapObject* result = nullptr;
  {
    AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
    if (!allocation.To(&result)) return allocation;
  }

  result->set_map_after_allocation(map);
  // Set length and hash fields of the allocated string.
  String* answer = String::cast(result);
  answer->set_length(str.length());
  answer->set_hash_field(hash_field);

  DCHECK_EQ(size, answer->Size());

  // Fill in the characters.
  MemCopy(answer->address() + SeqTwoByteString::kHeaderSize, str.start(),
          str.length() * kUC16Size);

  return answer;
}

AllocationResult Heap::CopyFixedArray(FixedArray* src) {
  if (src->length() == 0) return src;
  return CopyFixedArrayWithMap(src, src->map());
}


AllocationResult Heap::CopyFixedDoubleArray(FixedDoubleArray* src) {
  if (src->length() == 0) return src;
  return CopyFixedDoubleArrayWithMap(src, src->map());
}

AllocationResult Heap::AllocateFixedArray(int length, PretenureFlag pretenure) {
  return AllocateFixedArrayWithFiller(length, pretenure, undefined_value());
}

AllocationResult Heap::AllocateRaw(int size_in_bytes, AllocationSpace space,
                                   AllocationAlignment alignment) {
  DCHECK(AllowHandleAllocation::IsAllowed());
  DCHECK(AllowHeapAllocation::IsAllowed());
  DCHECK(gc_state_ == NOT_IN_GC);
#ifdef DEBUG
  if (FLAG_gc_interval >= 0 && !always_allocate() &&
      Heap::allocation_timeout_-- <= 0) {
    return AllocationResult::Retry(space);
  }
  isolate_->counters()->objs_since_last_full()->Increment();
  isolate_->counters()->objs_since_last_young()->Increment();
#endif

  bool large_object = size_in_bytes > kMaxRegularHeapObjectSize;
  HeapObject* object = nullptr;
  AllocationResult allocation;
  if (NEW_SPACE == space) {
    if (large_object) {
      space = LO_SPACE;
    } else {
      allocation = new_space_->AllocateRaw(size_in_bytes, alignment);
      if (allocation.To(&object)) {
        OnAllocationEvent(object, size_in_bytes);
      }
      return allocation;
    }
  }

  // Here we only allocate in the old generation.
  if (OLD_SPACE == space) {
    if (large_object) {
      allocation = lo_space_->AllocateRaw(size_in_bytes, NOT_EXECUTABLE);
    } else {
      allocation = old_space_->AllocateRaw(size_in_bytes, alignment);
    }
  } else if (CODE_SPACE == space) {
    if (size_in_bytes <= code_space()->AreaSize()) {
      allocation = code_space_->AllocateRawUnaligned(size_in_bytes);
    } else {
      allocation = lo_space_->AllocateRaw(size_in_bytes, EXECUTABLE);
    }
  } else if (LO_SPACE == space) {
    DCHECK(large_object);
    allocation = lo_space_->AllocateRaw(size_in_bytes, NOT_EXECUTABLE);
  } else if (MAP_SPACE == space) {
    allocation = map_space_->AllocateRawUnaligned(size_in_bytes);
  } else {
    // NEW_SPACE is not allowed here.
    UNREACHABLE();
  }
  if (allocation.To(&object)) {
    OnAllocationEvent(object, size_in_bytes);
  }

  return allocation;
}


void Heap::OnAllocationEvent(HeapObject* object, int size_in_bytes) {
  HeapProfiler* profiler = isolate_->heap_profiler();
  if (profiler->is_tracking_allocations()) {
    profiler->AllocationEvent(object->address(), size_in_bytes);
  }

  if (FLAG_verify_predictable) {
    ++allocations_count_;
    // Advance synthetic time by making a time request.
    MonotonicallyIncreasingTimeInMs();

    UpdateAllocationsHash(object);
    UpdateAllocationsHash(size_in_bytes);

    if (allocations_count_ % FLAG_dump_allocations_digest_at_alloc == 0) {
      PrintAllocationsHash();
    }
  }

  if (FLAG_trace_allocation_stack_interval > 0) {
    if (!FLAG_verify_predictable) ++allocations_count_;
    if (allocations_count_ % FLAG_trace_allocation_stack_interval == 0) {
      isolate()->PrintStack(stdout, Isolate::kPrintStackConcise);
    }
  }
}


void Heap::OnMoveEvent(HeapObject* target, HeapObject* source,
                       int size_in_bytes) {
  HeapProfiler* heap_profiler = isolate_->heap_profiler();
  if (heap_profiler->is_tracking_object_moves()) {
    heap_profiler->ObjectMoveEvent(source->address(), target->address(),
                                   size_in_bytes);
  }
  if (target->IsSharedFunctionInfo()) {
    LOG_CODE_EVENT(isolate_, SharedFunctionInfoMoveEvent(source->address(),
                                                         target->address()));
  }

  if (FLAG_verify_predictable) {
    ++allocations_count_;
    // Advance synthetic time by making a time request.
    MonotonicallyIncreasingTimeInMs();

    UpdateAllocationsHash(source);
    UpdateAllocationsHash(target);
    UpdateAllocationsHash(size_in_bytes);

    if (allocations_count_ % FLAG_dump_allocations_digest_at_alloc == 0) {
      PrintAllocationsHash();
    }
  }
}


void Heap::UpdateAllocationsHash(HeapObject* object) {
  Address object_address = object->address();
  MemoryChunk* memory_chunk = MemoryChunk::FromAddress(object_address);
  AllocationSpace allocation_space = memory_chunk->owner()->identity();

  STATIC_ASSERT(kSpaceTagSize + kPageSizeBits <= 32);
  uint32_t value =
      static_cast<uint32_t>(object_address - memory_chunk->address()) |
      (static_cast<uint32_t>(allocation_space) << kPageSizeBits);

  UpdateAllocationsHash(value);
}


void Heap::UpdateAllocationsHash(uint32_t value) {
  uint16_t c1 = static_cast<uint16_t>(value);
  uint16_t c2 = static_cast<uint16_t>(value >> 16);
  raw_allocations_hash_ =
      StringHasher::AddCharacterCore(raw_allocations_hash_, c1);
  raw_allocations_hash_ =
      StringHasher::AddCharacterCore(raw_allocations_hash_, c2);
}


void Heap::RegisterExternalString(String* string) {
  external_string_table_.AddString(string);
}


void Heap::FinalizeExternalString(String* string) {
  DCHECK(string->IsExternalString());
  v8::String::ExternalStringResourceBase** resource_addr =
      reinterpret_cast<v8::String::ExternalStringResourceBase**>(
          reinterpret_cast<byte*>(string) + ExternalString::kResourceOffset -
          kHeapObjectTag);

  // Dispose of the C++ object if it has not already been disposed.
  if (*resource_addr != NULL) {
    (*resource_addr)->Dispose();
    *resource_addr = NULL;
  }
}

Address Heap::NewSpaceTop() { return new_space_->top(); }

bool Heap::DeoptMaybeTenuredAllocationSites() {
  return new_space_->IsAtMaximumCapacity() && maximum_size_scavenges_ == 0;
}

bool Heap::InNewSpace(Object* object) {
  // Inlined check from NewSpace::Contains.
  bool result =
      object->IsHeapObject() &&
      Page::FromAddress(HeapObject::cast(object)->address())->InNewSpace();
  DCHECK(!result ||                 // Either not in new space
         gc_state_ != NOT_IN_GC ||  // ... or in the middle of GC
         InToSpace(object));        // ... or in to-space (where we allocate).
  return result;
}

bool Heap::InFromSpace(Object* object) {
  return object->IsHeapObject() &&
         MemoryChunk::FromAddress(HeapObject::cast(object)->address())
             ->IsFlagSet(Page::IN_FROM_SPACE);
}


bool Heap::InToSpace(Object* object) {
  return object->IsHeapObject() &&
         MemoryChunk::FromAddress(HeapObject::cast(object)->address())
             ->IsFlagSet(Page::IN_TO_SPACE);
}

bool Heap::InOldSpace(Object* object) { return old_space_->Contains(object); }

bool Heap::InNewSpaceSlow(Address address) {
  return new_space_->ContainsSlow(address);
}

bool Heap::InOldSpaceSlow(Address address) {
  return old_space_->ContainsSlow(address);
}

bool Heap::ShouldBePromoted(Address old_address) {
  Page* page = Page::FromAddress(old_address);
  Address age_mark = new_space_->age_mark();
  return page->IsFlagSet(MemoryChunk::NEW_SPACE_BELOW_AGE_MARK) &&
         (!page->ContainsLimit(age_mark) || old_address < age_mark);
}

void Heap::RecordWrite(Object* object, Object** slot, Object* value) {
  if (!InNewSpace(value) || !object->IsHeapObject() || InNewSpace(object)) {
    return;
  }
  store_buffer()->InsertEntry(reinterpret_cast<Address>(slot));
}

void Heap::RecordWriteIntoCode(Code* host, RelocInfo* rinfo, Object* value) {
  if (InNewSpace(value)) {
    RecordWriteIntoCodeSlow(host, rinfo, value);
  }
}

void Heap::RecordFixedArrayElements(FixedArray* array, int offset, int length) {
  if (InNewSpace(array)) return;
  for (int i = 0; i < length; i++) {
    if (!InNewSpace(array->get(offset + i))) continue;
    store_buffer()->InsertEntry(
        reinterpret_cast<Address>(array->RawFieldOfElementAt(offset + i)));
  }
}

Address* Heap::store_buffer_top_address() {
  return store_buffer()->top_address();
}

void Heap::CopyBlock(Address dst, Address src, int byte_size) {
  CopyWords(reinterpret_cast<Object**>(dst), reinterpret_cast<Object**>(src),
            static_cast<size_t>(byte_size / kPointerSize));
}

template <Heap::FindMementoMode mode>
AllocationMemento* Heap::FindAllocationMemento(Map* map, HeapObject* object) {
  Address object_address = object->address();
  Address memento_address = object_address + object->SizeFromMap(map);
  Address last_memento_word_address = memento_address + kPointerSize;
  // If the memento would be on another page, bail out immediately.
  if (!Page::OnSamePage(object_address, last_memento_word_address)) {
    return nullptr;
  }
  HeapObject* candidate = HeapObject::FromAddress(memento_address);
  Map* candidate_map = candidate->map();
  // This fast check may peek at an uninitialized word. However, the slow check
  // below (memento_address == top) ensures that this is safe. Mark the word as
  // initialized to silence MemorySanitizer warnings.
  MSAN_MEMORY_IS_INITIALIZED(&candidate_map, sizeof(candidate_map));
  if (candidate_map != allocation_memento_map()) {
    return nullptr;
  }

  // Bail out if the memento is below the age mark, which can happen when
  // mementos survived because a page got moved within new space.
  Page* object_page = Page::FromAddress(object_address);
  if (object_page->IsFlagSet(Page::NEW_SPACE_BELOW_AGE_MARK)) {
    Address age_mark =
        reinterpret_cast<SemiSpace*>(object_page->owner())->age_mark();
    if (!object_page->Contains(age_mark)) {
      return nullptr;
    }
    // Do an exact check in the case where the age mark is on the same page.
    if (object_address < age_mark) {
      return nullptr;
    }
  }

  AllocationMemento* memento_candidate = AllocationMemento::cast(candidate);

  // Depending on what the memento is used for, we might need to perform
  // additional checks.
  Address top;
  switch (mode) {
    case Heap::kForGC:
      return memento_candidate;
    case Heap::kForRuntime:
      if (memento_candidate == nullptr) return nullptr;
      // Either the object is the last object in the new space, or there is
      // another object of at least word size (the header map word) following
      // it, so suffices to compare ptr and top here.
      top = NewSpaceTop();
      DCHECK(memento_address == top ||
             memento_address + HeapObject::kHeaderSize <= top ||
             !Page::OnSamePage(memento_address, top - 1));
      if ((memento_address != top) && memento_candidate->IsValid()) {
        return memento_candidate;
      }
      return nullptr;
    default:
      UNREACHABLE();
  }
  UNREACHABLE();
}

void Heap::UpdateAllocationSite(Map* map, HeapObject* object,
                                PretenuringFeedbackMap* pretenuring_feedback) {
  DCHECK_NE(pretenuring_feedback, &global_pretenuring_feedback_);
  DCHECK(InFromSpace(object) ||
         (InToSpace(object) &&
          Page::FromAddress(object->address())
              ->IsFlagSet(Page::PAGE_NEW_NEW_PROMOTION)) ||
         (!InNewSpace(object) &&
          Page::FromAddress(object->address())
              ->IsFlagSet(Page::PAGE_NEW_OLD_PROMOTION)));
  if (!FLAG_allocation_site_pretenuring ||
      !AllocationSite::CanTrack(map->instance_type()))
    return;
  AllocationMemento* memento_candidate =
      FindAllocationMemento<kForGC>(map, object);
  if (memento_candidate == nullptr) return;

  // Entering cached feedback is used in the parallel case. We are not allowed
  // to dereference the allocation site and rather have to postpone all checks
  // till actually merging the data.
  Address key = memento_candidate->GetAllocationSiteUnchecked();
  (*pretenuring_feedback)[reinterpret_cast<AllocationSite*>(key)]++;
}


void Heap::RemoveAllocationSitePretenuringFeedback(AllocationSite* site) {
  global_pretenuring_feedback_.erase(site);
}

Isolate* Heap::isolate() {
  return reinterpret_cast<Isolate*>(
      reinterpret_cast<intptr_t>(this) -
      reinterpret_cast<size_t>(reinterpret_cast<Isolate*>(16)->heap()) + 16);
}

void Heap::ExternalStringTable::PromoteAllNewSpaceStrings() {
  old_space_strings_.reserve(old_space_strings_.size() +
                             new_space_strings_.size());
  std::move(std::begin(new_space_strings_), std::end(new_space_strings_),
            std::back_inserter(old_space_strings_));
  new_space_strings_.clear();
}

void Heap::ExternalStringTable::AddString(String* string) {
  DCHECK(string->IsExternalString());
  if (heap_->InNewSpace(string)) {
    new_space_strings_.push_back(string);
  } else {
    old_space_strings_.push_back(string);
  }
}

void Heap::ExternalStringTable::IterateNewSpaceStrings(RootVisitor* v) {
  if (!new_space_strings_.empty()) {
    v->VisitRootPointers(Root::kExternalStringsTable, new_space_strings_.data(),
                         new_space_strings_.data() + new_space_strings_.size());
  }
}

void Heap::ExternalStringTable::IterateAll(RootVisitor* v) {
  IterateNewSpaceStrings(v);
  if (!old_space_strings_.empty()) {
    v->VisitRootPointers(Root::kExternalStringsTable, old_space_strings_.data(),
                         old_space_strings_.data() + old_space_strings_.size());
  }
}


// Verify() is inline to avoid ifdef-s around its calls in release
// mode.
void Heap::ExternalStringTable::Verify() {
#ifdef DEBUG
  for (size_t i = 0; i < new_space_strings_.size(); ++i) {
    Object* obj = Object::cast(new_space_strings_[i]);
    DCHECK(heap_->InNewSpace(obj));
    DCHECK(!obj->IsTheHole(heap_->isolate()));
  }
  for (size_t i = 0; i < old_space_strings_.size(); ++i) {
    Object* obj = Object::cast(old_space_strings_[i]);
    DCHECK(!heap_->InNewSpace(obj));
    DCHECK(!obj->IsTheHole(heap_->isolate()));
  }
#endif
}


void Heap::ExternalStringTable::AddOldString(String* string) {
  DCHECK(string->IsExternalString());
  DCHECK(!heap_->InNewSpace(string));
  old_space_strings_.push_back(string);
}

Oddball* Heap::ToBoolean(bool condition) {
  return condition ? true_value() : false_value();
}

uint32_t Heap::HashSeed() {
  uint32_t seed = static_cast<uint32_t>(hash_seed()->value());
  DCHECK(FLAG_randomize_hashes || seed == 0);
  return seed;
}


int Heap::NextScriptId() {
  int last_id = last_script_id()->value();
  if (last_id == Smi::kMaxValue) {
    last_id = 1;
  } else {
    last_id++;
  }
  set_last_script_id(Smi::FromInt(last_id));
  return last_id;
}

void Heap::SetArgumentsAdaptorDeoptPCOffset(int pc_offset) {
  DCHECK(arguments_adaptor_deopt_pc_offset() == Smi::kZero);
  set_arguments_adaptor_deopt_pc_offset(Smi::FromInt(pc_offset));
}

void Heap::SetConstructStubCreateDeoptPCOffset(int pc_offset) {
  // TODO(tebbi): Remove second half of DCHECK once
  // FLAG_harmony_restrict_constructor_return is gone.
  DCHECK(construct_stub_create_deopt_pc_offset() == Smi::kZero ||
         construct_stub_create_deopt_pc_offset() == Smi::FromInt(pc_offset));
  set_construct_stub_create_deopt_pc_offset(Smi::FromInt(pc_offset));
}

void Heap::SetConstructStubInvokeDeoptPCOffset(int pc_offset) {
  // TODO(tebbi): Remove second half of DCHECK once
  // FLAG_harmony_restrict_constructor_return is gone.
  DCHECK(construct_stub_invoke_deopt_pc_offset() == Smi::kZero ||
         construct_stub_invoke_deopt_pc_offset() == Smi::FromInt(pc_offset));
  set_construct_stub_invoke_deopt_pc_offset(Smi::FromInt(pc_offset));
}

void Heap::SetGetterStubDeoptPCOffset(int pc_offset) {
  DCHECK(getter_stub_deopt_pc_offset() == Smi::kZero);
  set_getter_stub_deopt_pc_offset(Smi::FromInt(pc_offset));
}

void Heap::SetSetterStubDeoptPCOffset(int pc_offset) {
  DCHECK(setter_stub_deopt_pc_offset() == Smi::kZero);
  set_setter_stub_deopt_pc_offset(Smi::FromInt(pc_offset));
}

void Heap::SetInterpreterEntryReturnPCOffset(int pc_offset) {
  DCHECK(interpreter_entry_return_pc_offset() == Smi::kZero);
  set_interpreter_entry_return_pc_offset(Smi::FromInt(pc_offset));
}

int Heap::GetNextTemplateSerialNumber() {
  int next_serial_number = next_template_serial_number()->value() + 1;
  set_next_template_serial_number(Smi::FromInt(next_serial_number));
  return next_serial_number;
}

void Heap::SetSerializedTemplates(FixedArray* templates) {
  DCHECK_EQ(empty_fixed_array(), serialized_templates());
  DCHECK(isolate()->serializer_enabled());
  set_serialized_templates(templates);
}

void Heap::SetSerializedGlobalProxySizes(FixedArray* sizes) {
  DCHECK_EQ(empty_fixed_array(), serialized_global_proxy_sizes());
  DCHECK(isolate()->serializer_enabled());
  set_serialized_global_proxy_sizes(sizes);
}

void Heap::CreateObjectStats() {
  if (V8_LIKELY(FLAG_gc_stats == 0)) return;
  if (!live_object_stats_) {
    live_object_stats_ = new ObjectStats(this);
  }
  if (!dead_object_stats_) {
    dead_object_stats_ = new ObjectStats(this);
  }
}

AlwaysAllocateScope::AlwaysAllocateScope(Isolate* isolate)
    : heap_(isolate->heap()) {
  heap_->always_allocate_scope_count_.Increment(1);
}

AlwaysAllocateScope::~AlwaysAllocateScope() {
  heap_->always_allocate_scope_count_.Decrement(1);
}

}  // namespace internal
}  // namespace v8

#endif  // V8_HEAP_HEAP_INL_H_
